Technical field
[0001] The present disclosure relates to a thermostat for a radiator. The thermostat has
a base part, which is adapted to be fixed in relation to a valve of the radiator,
and a knob, which is attached, turnably around an axis, to the base part in such a
way that it can be used to change the setting of the thermostat within a given range
by turning the knob. The thermostat further includes at least a first adjustable limiter
defining an extreme setting, such that the knob is optionally rotatable only within
a sub-portion of said given range as defined by the first limiter.
Background
[0002] Such thermostates are widely used in connection with fluid conveying heating systems
in colder climates. The limiters may be used to make sure that the thermostat is correctly
used according to the circumstances of the particular installation. For instance,
it may be prevented by means of a limiter that the valve to which the thermostat is
connected is completely shut off to avoid freezing. It may further be avoided by means
of a limiter that the room temperature becomes too high, potentially saving plenty
of energy. Never-therless, one single thermostat type may be adapted to a number of
situations.
[0003] One problem associated with thermostates of this kind is how to make them easier
to use for installation professionals.
Summary
[0004] An object of the present disclosure is therefore to provide a thermostat that is
easier to use. This object is achieved by means of a thermostat as defined in claim
1. More specifically, a thermostat of the initially mentioned kind then further comprises
a releasing mechanism arranged for responding to axial movement of the knob, along
the axis around which it is turnable and relative to the base part, that releases
the limiter, such that the extreme setting can be changed.
[0005] This means that the setting can be changed simply by moving the knob to the extreme
setting position, pushing the knob in, turning the knob to a new setting, and releasing
the knob. No special tools are needed and the operation may be very quick. At the
same time, this function may be hidden to an end user, who may possibly be unauthorized
to change the extreme setting.
[0006] The thermostat may further comprise a second limiter, and the first limiter may define
a maximum setting, and the second a minimum setting, such that the knob is rotatable
only within a sub-portion of said given range between the minimum and maximum settings,
and wherein both the first and second limiter can be released by said axial movement
of the knob. This allows both a maximum and a minimum setting to be changed in this
way.
[0007] The first and second adjustable limiters may each comprise a ring and a tab attached
to the ring, the tab when defining a maximum or minimum setting being disposed in
a first groove compartment in the base portion, the release mechanism comprising a
ramp surface that, in response to the axial movement of the knob, lifts the tab out
of the first groove compartment, such that the tab can be moved to another groove
compartment corresponding to a different maximum or minimum setting. This is one convenient
way of arranging the limiter. The ring allows the limiter to be rotated around the
base part, and the tab provides the limiting function once in place in a groove compartment.
The ring and tab may be made in one piece in injection moulded plastic.
[0008] The tab may be adapted to straddle at least one wall in between two adjacent groove
compartments such that the tab extends into the two compartments. This allows for
a finer tuning of the maximum-mimimum settings, and may improve resistance to high
applied torques, turning the knob against a limiter.
[0009] Each tab may comprise, at its distal end, a radial projection that reaches radially
out of the groove compartment where the tab is located. The knob may be connected
to an inward projecting abutment portion that abuts such a radial projection when
reaching a maximum or minimum level.
[0010] The axial movement of the knob may be a movement towards a front cavity of the thermostat,
which is adapted for accommodating a connecting part of a radiator valve. Further,
a part of the knob may be covered by an outer sleeve, and the outer sleeve may comprise
a free space allowing the axial movement of the knob. A locking device may be provided,
e.g. in connection with the free space, preventing the axial movement of the knob
until the locking device has been released, in order to prevent unauthorized changing
of the settings.
Brief description of the drawings
[0011]
Fig 1 shows a thermostat.
Fig 2 is a cross section through a thermostat.
Fig 3 shows an enlarged portion of fig 2.
Fig 4 shows a part of a maximum-minimum arrangement.
Fig 5 shows a minimum ring alone.
Fig 6 shows a thermostat with the knob removed to expose a maximum-minimum arrangement.
Fig 7 shows an enlarged portion of fig 6.
Fig 8 shows a cross section corresponding to fig 3, but in a mode where maximum-minimum
setting can be carried out.
Fig 9 shows an enlarged portion of fig 8.
Fig 10 shows an alternative embodiment of the base part and the maximum/minimum rings.
Fig 11 shows an enlarged portion of fig 10.
Detailed description
[0012] The present disclosure relates to a thermostat for a radiator. An example of a thermostat
1 is shown in fig 1 and includes a connecting nut 3, for connecting the thermostat
1 to the valve (not shown in fig 1) of a radiator, and a sleeve 5, which is fixed
in relation to the valve when the connecting nut 3 is tightened. The thermostat further
comprises a knob 7 that is turnably attached to a base part 9, which is connected
to the sleeve 5, in such a way that the knob 7 can be used to change the setting of
the thermostat, and as a result change the flow of a heating medium through the radiator.
In the illustrated case, a window 11 is provided in the sleeve 5, and a digit "5"
marked on the knob is visible through the window to indicate the present setting of
the thermostat.
[0013] Fig 2 is a cross section through a thermostat, and fig 3 shows an enlarged portion
of fig 2. The thermostat is built on the base part 9, which has a front cavity 15
for accommodating the connecting part of a radiator valve, to which the thermostat
is firmly connected by means of the nut 3. The inner walls of the front cavity 15
may as illustrated be fluted, and the opposing surfaces of the valve connecting part
may be fluted as well to prevent that the thermostat swivels around the valve. As
mentioned, a connecting nut 3 of the thermostat can be tightened to a corresponding
threaded part on the valve in order to fix the thermostat to the valve.
[0014] The knob 7 is formed as a hollow cylinder, and a circumferential collar portion 17
at its inner end (facing the valve) may be arranged to rest against a circumferential
shoulder portion 19 on the base part 9, such that the knob 7 can rotate around the
base part 9, but is prevented from moving further away from the valve. The collar
portion 17 of the knob 7 may be urged against the shoulder portion 19 of the base
part 9 by means of a spring (not shown) which may be arranged in a space 12 between
the base part 9 and and an intermediate member 29 that will be discussed further later.
The outer end of the knob 7 cylinder is closed by an end lid 23.
[0015] The sleeve 5 is fixedly attached to the base part 9 and may as illustrated reach
out and cover the inner part of the knob 7 to provide some constructional stability
and to provide the aforementioned indicating window. The indicating digits, e.g. "5"
shown in fig 1, are placed on the part of the knob 7 that are covered by the sleeve
5. A free space 25 may be provided in the sleeve 5 at the inner end of the knob cylinder,
to allow the knob 7 to be moved a few millimetres inwards, as will be discussed later.
[0016] Inside the knob 7, a sensor holder 27 is disposed, which has an overall hollow cylindrical
shape. The sensor holder 27 is attached to the knob 7 via an intermediate member 29
attached to the knob. The intermediate member 29 presents a fluted inner cylindrical
surface to a correspondingly fluted flange 31 of the sensor holder 27, which means
that the intermediate member 29 fixes the sensor holder 27 radially, and forces the
sensor holder 27 to rotate with the knob 7, while allowing a linear movement relative
to the knob 7 along the aforementioned axis (cf. 10, fig 1). At the same time, the
front part of the sensor holder, closest to the radiator, is in threaded engagement
with the base part 9. This means that turning the knob 7 will displace the sensor
holder 27 axially within the thermostat.
[0017] A wax sensing element 33 in a casing, which is not shown in cross section in fig
2, is disposed within the sensor holder 27 and rests against an inward facing collar
portion 35 at the rear end thereof as seen from the radiator. The wax sensing element
33 reacts on changing ambient room temperature by expanding and contracting as is
well known per se. The wax sensing element 33 influences a piston 37, 39, 41, a part
of which 37 reaches into the casing of the wax sensing element 33. A region 41 at
the opposing end of the piston in turn operates against the pin of the radiator valve
to which the thermostat is connected. The piston with an inner overload spring 21
are enclosed in a front part of the sensor holder. A spring in the valve urges via
the radiator pin the piston against the wax sensor element 33 in order to obtain a
correct displacement of the piston 37 when the wax sensing element 33 contracts. The
piston itself can contract in the case of an overload condition, if the force of the
compressed overload spring 21 is overcome, such that the front parts 41, 39 move closer
to the part 37, reaching into the wax sensor. The ability to axially adjust the position
of the sensor holder means that a user can set the valve-thermostat characteristics
such that a desired room temperature is obtained.
[0018] As such, the thermostate is capable to be adjusted to a wide range target room temperatures.
In many cases however, it is desired to optionally limit this range into a narrower
range. For instance, a landlord may want to limit the energy consumption during cold
seasons which implies that the maximal setting should be limited. Further, to avoid
risk of freezing, it may be desired to limit the minimal setting as well.
[0019] Figs 4-7 illustrate together with the aforementioned fig 3, a maximum-minimum arrangement
that can be used to achieve this feature. Fig 4 shows a maximum ring 47 and a minimum
ring 45 assembled together. Fig 5 shows the minimum ring 45 alone. The minimum ring
45 and the maximum ring 47 may be made in a plastic material by injection moulding,
and may be more or less identical save for a small difference in diameter, such that
one may be slipped over the other. The minimum ring 45 and the maximum ring 47 are
each formed in one piece with a maximum tab 49 and a minimum tab 51, respectively,
which project from each ring in an axial direction. When assembled, as shown in fig
6, the maximum and minimum rings 47, 45 are attached slipped over the base part 9,
surrounding the latter, and each of the maximum tab 49 and the minimum tab 51 are
snapped into a groove compartment 53 (also visible in fig 3) in the base part periphery.
As the rings 45, 47 are attached slipped over the base part 9, they may rotate around
the base part when the respective tab 49, 51 is lifted from its groove compartment.
[0020] Fig 6 shows the intermediate member 29, connected to the knob (cf. 7 fig 2), which
knob is removed in fig 6 to more clearly reveal the maximum-minimum arrangement. The
intermediate member 29, at the end where the tabs 49, 51 are located, has an inward
projecting abutment portion 55 as is more clearly shown in the enlarged view of fig
7. The abutment portion reaches almost down to the walls 57 that define the groove
compartments 53 but still allows the intermediate member 29 to rotate freely, except
past a groove compartment 53 where a maximum or minimum tab is located.
[0021] As is shown e.g. in fig 4 each tab 49, 51 comprises, at its end, a radial projection
59, 61 that reaches out of the groove compartment where the tab is located. When reaching
a tab, the abutment portion 55 of the intermediate member will therefore abut the
radial projection 59, 61, and will not be able to rotate further as the tab is trapped
in the groove compartment 53. As is illustrated in the enlarged cross section fo fig
3, an inward facing surface 64 of the intermediate member 29 prevents the tab 51 from
leaving the groove compartment in this state. However, the tab 51 may also have a
shape that urges the tab into the groove compartment, providing a pre-tension towards
the centre line of the thermostat.
[0022] In the situation shown in fig 6, the range has been extremely limited, as only one
free groove compartment 53 exists between the maximum and minimum tabs 49, 51. This
is mainly done for illustration purposes, but may be useful in a real situation where
a termostat should be more or less fixed to a setting. The knob can only be turned
a few degrees, resulting in a very small axial adjustment of the sensor holder.
[0023] The present disclosure provides for a very simple adjustment of the maximum-minimum
arrangement. In the intermediate member 29, at both sides of the abutment portion
55, there is provided a ramp surface 63, 65 in front of a position where the maximum
or minimum tab 49, 51 is located when coming into contact with the abutment portion
55. As previously mentioned, the free space 25 provided in the sleeve 5 (cf. fig 2)
at the inner end of the knob cylinder, allows the knob 7 to be moved a few millimetres
towards the radiator valve. This allows, starting from the position best shown in
fig 3, the ramp surface 65 to interact with a correspondingly sloped surface 67 (hidden
in fig 6, cf. fig 3) on the inner side of the tab 51 and to lift the tab 51 out of
the groove compartment where it has been trapped.
[0024] This state is illustrated in fig 8 and in the enlarged portion of fig 9, where the
sloped surface 67 rises on the ramp surface 65 forcing the tab 51 out of the groove
compartment 53. In this state, by rotating the knob 7, the lifted tab 51 and its corresponding
ring 47 can be freely rotated in any direction to another groove compartment where
the tab 51 can be placed by releasing the knob 7. The movement is however still limited
by the other tab that remains in its groove compartment. The knob 7 returns to the
initial axial position by means of a return spring (not shown), and the tab snaps
into said another groove compartment.
[0025] Thus, by turning the knob e.g. to the maximum setting, pushing the knob in, rotating
the knob in either direction, and releasing the knob, the maximum setting can be adjusted.
The minimum setting can be adjusted in the same way. The maximum-minimum settings
can therefore be changed easily, without the use of tools.
[0026] Fig 10 shows an alternative embodiment of the base part and the maximum/minimum rings
in a perspective view as seen from the end distant from the location of the radiator
valve. In this embodiment, the groove compartments 71 have been made narrower (about
1 mm as compared to about 3 mm in the version shown in fig 7), such that a much higher
number of such grooves can be provided for a given circumference. This allows for
a finer tuning of the maximum mimimum settings. The tab, 73 can be modified such that
it is capable of straddling one wall 75 in between two adjacent groove compartments
71. Thereby, the tab 73 can be inserted into the two groove compartments. In addition
to providing an additional structural strength to the tab itself, this reduces the
stress on each wall portion 75 in the tangential direction when the tab 73 acts as
a stop, since that stress becomes split between two such walls. As illustrated in
fig 11, only one of the tab parts exending into the groove compartments need be provided
with a ramp surface 77, such that the other part may have a greater structural strength.
[0027] A locking device may be provided e.g. in the free space 25 of fig 2 preventing the
axial movement of the knob 7 until e.g. a sprint (not shown) extending through the
sleeve 5 has been removed, if unauthorized changing of the max/min settings is to
be prevented.
[0028] The present disclosure is not restricted to the embodiments shown and may be varied
in different ways within the scope of the appended claims. For instance, while the
present disclosure illustrates a thermostat where the limiters become adjustable by
pushing the knob towards the radiator valve, the skilled person could consider a varied
embodiment where the knob is instead pulled away from the radiator valve to achieve
the same effect. Additionally, it may be considered to use only one limiter, with
a single, extreme (max or min) setting. Further, an embodiment could be considered
where a tab extends in the opposite direction from its corresponding ring, i.e. in
the direction towards the radiator. In such a case, the ring may instead be attached
to the intermediate part and may be designed to enter a groove compartment in the
base portion.
1. A thermostat (1), for a radiator, including a base part (9), which is adapted to be
fixed in relation to a valve of the radiator, and a knob (7), which is attached, turnably
around an axis (10), to the base part in such a way that it can be used to change
the setting of the thermostat within a given range by turning the knob, and at least
a first adjustable limiter (47, 49), the first limiter (47, 49) defining an extreme
setting, such that the knob (7) is optionally rotatable only within a sub-portion
of said given range as defined by the first limiter, characterized in further comprising a releasing mechanism (63, 65) arranged for responding to axial
movement of the knob (7), along said axis (10) and relative to the base part (9),
that releases the first limiter (47, 49), such that the extreme setting can be changed.
2. A thermostat according to claim 1, further comprising a second limiter (45, 51), wherein
the first limiter defines a maximum setting, and the second limiter defines a minimum
setting, such that the knob (7) is rotatable only within a sub-portion of said given
range between the minimum and maximum settings, and wherein both the first and second
limiter can be released by said axial movement of the knob.
3. A thermostat according to claim 2, wherein the first and second adjustable limiters
each comprise a ring (45, 47) and a tab (49, 51, 73) attached to the ring, the tab
when defining a maximum or minimum setting being disposed in at least a first groove
compartment (53) in the base portion (9), the release mechanism comprising a ramp
surface that, in response to the axial movement of the knob (7), lifts the tab out
of the first groove compartment (53), such that the tab can be moved to another groove
compartment corresponding to a different maximum or minimum setting.
4. A thermostat according to claim 3, wherein a tab (73) is adapted to straddle at least
one wall (75) in between two adjacent groove compartments (71) such that the tab extends
into two compartments.
5. A thermostat according to claim 3 or 4, wherein the ring (45) and tab (51) are made
in one piece in injection moulded plastic.
6. A thermostat according to any of claims 3-5, wherein each tab (49, 51) comprises,
at its end, a radial projection (59, 61) that reaches radially out of the groove compartment
(53) where the tab is located, and wherein the knob (7) is connected to an inward
projecting abutment portion (55) that abuts either of said radial projections (59,
61) when reaching a maximum or minimum setting.
7. A thermostat according to any of the preceding claims, wherein said axial movement
of the knob (7) is a movement towards a front cavity (15) of the thermostat, adapted
for accommodating a connecting part of a radiator valve.
8. A thermostat according to claim 7, wherein a part of the knob (7) is covered by an
outer sleeve (5), and said outer sleeve comprises a free space (25) allowing said
axial movement of the knob (7).
9. A thermostat according to any of the preceding claims, wherein a locking device is
provided preventing the axial movement of the knob (7) until the locking device has
been released.